Titania fiber, method for producing the fiber and method for using the fiber

ABSTRACT

A continuous fiber of titania are made having an average diameter per a monofilament of from 5 to 50 μm, which has a BET specific surface area of 10 m 2  /g or more, a pore volume of 0.05 cc/g or more, a volume of pores having a pore diameter of not less than 10 angstroms being 0.02 cc/g or more and an average tensile strength per a monofilament of 0.1 GPa or more, or which has an average tensile strength per a monofilament of 0.5 GPa or more.

FIELD OF THE INVENTION

The present invention relates to a continuous fiber of titania which canbe used as, for example, a carrier for carrying type catalyst which canbe used for reduction of a nitrogen oxide and oxidation of an organiccompound, a photocatalyst, a filter for high temperature, an electronicmaterial and a reinforcing filler, and a method for producing the fiberan a method for using the fiber.

The present invention also relates to a catalyst component-carryingtitania fiber which can be used for reduction of a nitrogen oxide andoxidation of an organic compound, and a method for producing thecatalyst component-carrying titania fiber and a method for using thecatalyst component-carrying titania fiber.

BACKGROUND OF THE INVENTION

Heretofore, a titanium oxide has been used as a catalyst carrier for,for example, reducing a nitrogen oxide and oxidizing an organiccompound, wherein the carrier holds a catalyst component (e.g. amaterial selected from a metal such as V, W, Al, As, Ni, Zr, Mo, Ru, Mg,Ca and Pt, its oxide and its complex oxide.) The titanium oxide is alsoused as a photocatalyst or a carrier for photocatalyst. The titaniumoxide is normally used in the form of a powder, a particle or pellet.

With a recent expansion in use of the titanium oxide, somecharacteristics have been required, but they can not be accomplished bythe above conventional forms of titanium oxide. In order to cope withthe requirements, various titania fibers have been developed.

However, these titania fibers have problems that the length of eachfiber is about several millimeters (in other words, the fibers areso-called short fibers) and the mechanical strength of the fibers is notsufficient.

The following methods (1) to (7) have hitherto been known for producingtitania fibers:

(1) a method comprising the steps of subjecting a potassium titaniafiber as a starting material to a depotassiumation treatment in an acidsolution and calcining the resultant to produce a titania fiber (seeJP-A-53-41518, JP-A-53-52737, JP-A-55-113625, JP-B-59-41928,JP-A-1-246139 and JP-A-2-164722);

(2) a method comprising the steps of spinning polytitanoxane to obtain aprecursor fiber and calcining the precursor fiber to produce a titaniafiber (JP-A-49-124336);

(3) a method comprising the steps of concentrating an water-miscibletitania sol obtained by adding a titanium alkoxide in a concentratedhydrochloric acid to form a spinning solution, spinning the titania soland calcining the resultant to obtain a titania fiber (U.S. Pat. No.4166147);

(4) a method comprising the steps of adding water and hydrochloric acidto an alcohol solution of titanium tetraisopropoxide to hydrolyze thepropoxide, carrying out polycondensation to form a spinning solution andspinning the resulting condensation product to obtain a titania fiber (aso-called sol-gel method)(JP-A-62-223323);

(5) a method comprising the steps of reacting a titanium alkoxide withan aliphatic dicarboxylic acid in a solvent to prepare a polymer,concentrating the reaction mixture, spinning the polymer and calciningthe resultant to obtain a titania fiber (JP-A-60-104133);

(6) a method comprising the steps of wet-spinning an arginic acidsolution to form a continuous fiber, immersing the continuous fiber in atitanium solution, drying the continuous fiber with stretching andcalcining to produce a titania fiber (JP-A-2-184525); and

(7) a method comprising the steps of impregnating an organic fiber withan aqueous titanium alkoxy hydrogen peroxide solution and calcining thefiber to it produce a titania fiber (JP-A-2-19569).

It has proven difficult to produce a so-called continuous fiber oftitania having a length of at least several tens centimeters, excellentspinning stability and excellent mechanical strength in an industriallyeasy manner by the above-disclosed conventional methods. Additionally,the conventional methods suffer from various drawbacks.

According to method (1), the resulting fiber is a so-called short fiberwherein a fiber length is normally not more than 1 mm, and at most aboutseveral millimeters. It is impossible to produce a continuous fiber.According to method (3), a water-miscible titania sol is used to form aspinning solution. The use of the high-concentrated inorganic acid (e.g.concentrated hydrochloric acid, etc.) to produce the sol restricts thechoice of material for the vessel and means that chlorine derived fromconcentrated hydrochloric acid remains as an impurity contaminating inthe resulting fiber.

According to the sol-gel method (4), titanium alkoxide is hydrolyzed andpolycondensated in the presence of an acid such as hydrochloric acid toobtain a viscous solution having suitable spinnability, which is used asa spinning solution. In the method (4), it is difficult to control thehydrolysis reaction and the polycondensation reaction and the spinnableviscous solution is easily converted into a solution which can not bespun.

According to method (5) the residual amount of an organic component inthe polymer is large and the content of the organic component in theprecursor fiber is necessarily high as a result of reacting a titaniumalkoxide with an aliphatic dicarboxylic acid in a solvent to prepare apolymer, since an organic group exists in a side chain and betweentitanium atoms of the polymer. According to the method (6) ofwet-spinning an arginic acid solution and immersing the resulting fiberin a titanium solution and according to the method (7) of impregnatingan organic fiber with an aqueous titanium alkoxy hydrogen peroxidesolution, the residual amount of an organic component in a precursorfiber is large. When a titania fiber is obtained by calcining theprecursor fiber containing a large residual amount of the organiccomponent, there is a problem that the mechanical strength of theresulting fiber is low.

Since there is no need to use an organic polymer and a binder accordingto the method (2), a continuous fiber having high mechanical strength tosome degree is obtained. However, a continuous fiber having satisfactorymechanical strength is not always obtained.

As described above, a conventional titania fiber does not satisfyrequired characteristics criteria for a continuous fiber of titaniahaving excellent spinning stability and high mechanical strength.Additionally, for example, when used as a catalyst carrier, it isparticularly required that specific surface area and pore volume of thefiber are high. Nevertheless, those of the conventional titania fiberare not high. When used as a catalyst carrier for reduction of anitrogen oxide, it is particularly required that the crystal form is ananatase. Nevertheless, it is very difficult to obtain a titania fiberhaving this crystal form in the conventional methods.

Even in a method comprising steps of immersing a titania fiber in anacid to partially corrode the surface of the fiber for the purpose ofincreasing the specific surface area, which is based on a conventionalmethod of using a fiber of silica, alumina, etc. as a catalyst carrier(described in JP-A-50-87974 AND JP-B-8-11196), there are problems thatit is difficult to form uniform pores on the surface of the fiber andthe mechanical strength of the fiber is quite low as compared with afiber of silica and/or alumina, and that this partially corroding methoditself is complicated.

On the other hand, as a method of carrying a catalyst component onand/or in a titania fiber, the following methods are also known but allmethods are not sufficient.

For example, JP-A-5-184923 discloses that a vanadium oxide-carryingtitania fiber is obtained by heat-treating an amorphous fiber to deposita crystal of an anatase-form titanium oxide and a crystal of a vanadiumoxide. In this method, the amorphous fiber was produced by a sol-gelmethod of hydrolyzing a alkoxide in a solution of a titanium alkoxideand a vanadium compound or hydrolyzing alkoxides in a solution of atitanium alkoxide, the other alkoxide and a vanadium compound, followedby gelation. However, the titania fiber obtained by this method hasproblems in that, since an amorphous titanium oxide phase andanatase-form titanium oxide phase coexist, the shape of the fiber cannot be sufficiently retained and the catalystic activity removing anitrogen oxide is low.

JP-A-6-134306 discloses that a catalyst-carrying titania fiber isobtained by forming a polymer including titanium and silicon fromorganic alkoxides of titanium alkoxide and a silicon alkoxide by asol-gel method, spinning to form a fiber, drying and calcining the fiberto obtain a fiber of TiO₂ --SiO₂, and carrying vanadium pentaoxideand/or tungsten oxide. According to this method, a titania fiber havingan anatase crystal is obtained, however, physical properties such asspecific surface area and pore volume are not satisfactory, necessarily.

SUMMARY AND OBJECTS OF THE INVENTION

The present inventors have devoted intensive efforts to discover acontinuous fiber of titania having excellent spinning stability and highmechanical strength and a continuous fiber of titania having largespecific surface area and large pore volume, which are suitable as acatalyst carrier, and methods for producing continuous fibers of titaniaon an industrial scale. As a result, the present inventors havediscovered a continuous fiber of titania having excellent spinningstability and high mechanical strength which is obtainable on anindustrial scale by hydrolyzing and polymerizing a titanium alkoxideunder specified conditions, dissolving the resulting polymer in thepresence of a specified solution, spinning by using of the resultingsolution as a spinning solution, followed by calcination and,furthermore, that a continuous fiber of titania having extremely largespecific surface area and pore volume is obtainable by subjecting aprecursor fiber of titania to a water vapor treatment before and/orduring calcination.

The present inventors have also discovered the combination of a titaniafiber carrying a catalyst component, wherein the titania fiber has largeactive surface area and large pore volume. The catalyst component of thetitania fiber hardly comes off and high activity can be maintained for along period of time.

The present invention accomplished the foregoing and other objective byfirst providing a continuous fiber of titania wherein an averagediameter per a monofilament is from 5 to 50 μm and a tensile strengthper a monofilament is 0.1 GPa or more. Particularly, the presentinvention provides a continuous fiber of titania wherein the averagediameter per a monofilament is from 5 to 50 μm and the average tensilestrength per a monofilament is 0.5 GPa or more.

The present invention secondly provides a method for producing acontinuous fiber of titania, which comprises adding water to an alcoholsolution of a titanium alkoxide to carry out a hydrolysis reaction and apolymerization reaction of the titanium alkoxide, forming and depositinga polymer which is insoluble in the alcohol, dissolving the polymer inthe presence of an organic solvent in which the polymer dissolves toform a spinning solution, spinning by using the solution to obtain aprecursor fiber, and calcining the precursor fiber to obtain saidcontinuous fiber.

The present invention thirdly provides a method of using the continuousfiber of titania of the above first embodiment as a carrier forcarrying-type catalyst, a photocatalyst, a filter for high temperature,an electronic material and a reinforcing filler.

The present invention provides, fourth, a continuous fiber of titaniawherein the average diameter per a monofilament is from 5 to 50 μm, theBET specific surface area is 10 m² /g or more, the pore volume is 0.05cc/g or more, the volume of pores having a pore diameter of not lessthan 10 angstroms is 0.02 cc/g or more, and the average tensile strengthper a monofilament is 0.1 GPa or more.

The present invention provides as a fifth embodiment a method forproducing a continuous fiber of titania which comprises adding water toan alcohol solution of a titanium alkoxide to carry out a hydrolysisreaction and a polymerization reaction of the titanium alkoxide, formingand depositing a polymer which is insoluble in the alcohol, dissolvingthe polymer in the presence of an organic solvent in which the polymerdissolves to form a spinning solution, spinning by using the solution toobtain a precursor fiber, subjecting the resulting precursor fiber to awater vapor treatment before and/or during calcination and calcining theprecursor fiber to obtain said continuous fiber.

The present invention provides as a sixth embodiment a method of usingthe continuous fiber of titania of the above fourth embodiment as acarrier for carrying-type catalyst, a photocatalyst, a filter for hightemperature, an electronic material or a reinforcing filler.

The present invention provides as a seventh embodiment a catalystcomponent-carrying titania fiber prepared by carrying a catalystcomponent on and/or in the continuous fiber of titania of the abovefirst embodiment or of the above fourth embodiment.

The present invention provides as an eight embodiment a method forproducing the catalyst component-carrying titania fiber which comprisesthe combination of steps of immersing the continuous fiber of titania ofthe above first embodiment or of the above fourth embodiment in asolution containing a catalyst component selected from a metal, itsoxide and its complex oxide, drying and calcinating the fiber.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1 shows the outer surface appearance of the catalystcomponent-carrying titania fiber of the present invention (see Example22).

FIG. 2 shows the outer surface appearance of the catalystcomponent-carrying titania fiber made from a titania fiber having a BETspecific surface of 0.4 m² /g and a pore volume of less than 0.01 cc/g(see Comparative Example 3).

DETAILED DESCRIPTION OF THE INVENTION

In the first embodiment of the present invention, the continuous fiberof titania has physical properties wherein the average diameter per amonofilament is from 5 to 50 μm and the average tensile strength per amonofilament is 0.5 GPa or more. The average tensile strength ispreferably 0.85 GPa or more. Since the titania fiber has a highmechanical strength, it is preferably used when a titania fiber in aform of a fabric or a nonwoven fabric is needed. This titania fiber is acontinuous fiber and has a length of at least several tens centimeters,and preferably has a length of 50 cm or more.

In the second embodiment of the present invention, the continuous fiberof titania has an average diameter per a monofilament of from 5 to 50μm, a BET specific surface area of 10 m² /g or more, a pore volume of0.05 cc/g or more, a volume of pores having a pore diameter of not lessthan 10 angstroms of 0.02 cc/g or more, and an average tensile strengthper a monofilament of 0.1 GPa or more (hereinafter referred to as a"porous titania fiber"). It is obtained by subjecting a precursor fiberto a water vapor treatment before and/or during calcination in theproduction process. This titania fiber is also a continuous fiber andhas a length of at least several tens centimeters, and preferably has alength of 50 cm or more.

When the porous titania fiber of the present invention is used as acatalyst carrier or used as a catalyst, it especially maintains a highcatalytic activity for a long period of time because the BET specificsurface area is of 10 m² /g or more.

Regarding the porous titania fiber of the present invention, the porevolume measured by the nitrogen adsorption method is 0.05 cc/g or more,and is preferably from 0.10 cc/g to 1.0 cc/g. When the porous titaniafiber of the present invention is used as a catalyst carrier or used asa catalyst, it maintains high catalytic activity for a long period oftime because the pore volume is 0.05 cc/g large.

In the porous titania fiber of the present invention, the volume ofpores having a pore diameter of not less than 10 angstroms is 0.02 cc/gor more, and is preferably 0.04 cc/g or more.

The volume of pores having a pore diameter of not less than 10 angstromsis 0.02 cc/g or more, in particular, the peak of a pore diameter iswithin the range from about 10 to 300 angstroms, and is preferablywithin the range from about 10 to 100 angstroms. Therefore, the poroustitania fiber of the present invention is superior in catalyticretention and catalytic activity. Additionally, the porous titania fiberhas a high mechanical strength enough to be used as a catalyst carrier.If the volume of pores having a pore diameter of not less than 10angstroms is less than 0.02 cc/g, the catalyst may not sufficiently beimpregnated in the pores, e.g., a sufficiently carried catalyst, wherebysatisfactory catalytic activity can not be obtained. If said volume isless than 0.02 cc/g, the catalyst may also be physically separated fromthe titania fiber and the catalytic activity may not be maintained.

The porous titania fiber of the present invention exhibits an averagetensile strength per a monofilament is 0.1 GPa or more, and ispreferably 0.3 GPa or more. The porous titania fiber of the presentinvention has a high mechanical strength required as a catalyst carrier.When higher tensile strength is required, for example, when the titaniafiber is used in the form of a fabric or a nonwoven fabric, the firstcontinuous titania fiber having the high tensile strength of 0.5 of GPaor more of the present invention is preferably used.

A suitable titanium alkoxide for use in producing the titania fiber ofthe present invention is preferably represented by the general formula[1]:

    Ti(OR.sup.1).sub.4                                         [ 1]

wherein R¹ represents an alkyl group having 1 to 4 carbon atoms and eachof four R¹ in the formula [1] can be different from one another.Specific examples thereof include titanium tetramethoxide, titaniumtetraethoxide, titanium tetra-n-propoxide, titanium tetra-iso-propoxide,titanium tetra-n-butoxide, titanium tetra-sec-butoxide, titaniumtetra-tert-butoxide, titanium mono-methoxy-tri-iso-propoxide, titaniumdi-methoxy-di-iso-propoxide and the like. Among them, titaniumtetra-iso-propoxide, whose R¹ in the general formula [1] is an isopropylgroup, is preferable. In the case of those wherein the number of carbonatoms of R¹ in the general formula [1] exceeds 4, the content of theorganic component in the precursor fiber increases and, therefore, themechanical strength of the resulting titania fiber is liable to bereduced. Not only one kind of titanium alkoxide but also two or morekinds of titanium alkoxide can be used at the same time in the presentinvention.

A suitable alcohol for use in the present invention is preferablyrepresented by the general formula [2]:

    R.sup.2 OH                                                 [2]

wherein R² represents an alkyl group having 1 to 4 carbon atoms.Specific examples thereof include methanol, ethanol, isopropyl alcohol,n-buthylalcohol and the like. When the number of carbon atoms of R² inthe general formula [2] exceeds 4, a boiling point of the alcohol ishigh and, therefore, it becomes difficult to remove the alcohol in thepost-treatment step in the production process. The suitable boilingpoint is less than the boiling point for pentyl alcohol, and is lessthan about 140° C.

The production of the titania fiber of the present invention ischaracterized by adding water to an alcohol solution of a titaniumalkoxide to carry out the hydrolysis and polymerization reaction of thetitanium alkoxide, thereby producing and depositing a polymer which isinsoluble in the alcohol but dissolves in the presence of the otherorganic solvent. In the step of the hydrolysis and polymerizationreaction of the titanium alkoxide by using the alcohol solution, whenthe hydrolysis and polymerization reaction is carried out by using asolvent other than the alcohol, e.g. ethers, in place of the alcohol,the resulting polymer is liable to have a three-dimensional networkstructure and is easily gelated in the form of incorporating the solventand, therefore, a polymer having suitable polymerization degree like thepolymer of the present invention can not be produced. The polymerizationdegree of the polymer in the present invention is a polymerizationdegree to the degree where the polymer is insoluble in the alcohol butdissolve in an organic solvent other than the alcohol.

In the production of the titania fiber of the present invention, anamount of the alcohol to be used relative to the titanium alkoxide maybe an amount where the alkoxide and water does not become an immisciblestate in the hydrolysis reaction and is not specifically limited, and ispreferably within the range from about 0.5 to 50 mole per 1 mole of thetitanium alkoxide. Even if the amount is too large, no problem arises,but the cost required to separate the alcohol from the alcoholsuspension of the polymer in the post-treatment step becomes higher.

In the production of the titania fiber of the present invention, wateris added to an alcohol solution of a titanium alkoxide to carry out ahydrolysis reaction and a polymerization reaction of the titaniumalkoxide, thereby forming a polymer which is insoluble in the alcoholsolution. In order to control the hydrolysis reaction and thepolymerization reaction, a compound having active hydrogen may becontained in the alcohol solution. Examples thereof are an alkylsalicylate whose alkyl group has 1 to 4 carbon atoms, and a β-diketonewhich is represented by the general formula [4]:

    R.sup.4 COCH.sub.2 COR.sup.5                               [ 4]

wherein R⁴ and R⁵, independently of each other, represent an alkyl oralkoxy group having 1 to 4 carbon atoms.

Specific examples thereof include β-diketone such as ethyl acetoacetate,isopropyl acetoacetate, and alkyl salicylate such as ethyl salicylate,methyl salicylate. By including the compound having active hydrogen inthe alcohol solution, the hydrolysis reaction and the polymerizationreaction of the titanium alkoxide are controlled. This makes it possibleto improve the solubility of the polymer, in the presence of the organicsolvent although the polymer is deposited in the alcohol.

In the present invention, an amount of the compound having activehydrogen to be contained in the alcohol solution is preferably fromabout 0.05 to 1.9 mole per 1 mole of the titanium alkoxide, and is morepreferably from about 0.1 to 1.0 mole per 1 mole of the titaniumalkoxide. When the amount of the compound having active hydrogen issmaller than about 0.05 mole per 1 mole of the titanium alkoxide, theeffect of the compound having active hydrogen does not appearsufficiently. On the other hand, when the amount is larger than about1.9 mole, it is liable that the hydrolysis reaction and thepolymerization reaction are inhibited and, therefore, the polymerizationdoes not proceed easily and that the residual amount of the organiccomponent in the resulting polymer increases. As a result, themechanical strength of the resulting titania fiber tends to be lowered.

In the production of the titania fiber of the present invention, thehydrolysis reaction and the polymerization reaction of the titaniumalkoxide are carried out by adding water to the alcohol solution of thetitanium alkoxide, thereby forming and depositing a polymer which isinsoluble in the alcohol. An amount of water to be used may be an amountto the degree where the polymer is insoluble in the alcohol solution butdissolves in the presence of an organic solvent other than the alcohol.The amount is normally from about 1.5 to 4 mole per 1 mole of thetitanium alkoxide, but is not specifically limited. It is enough if theamount of a difference [A-B], which is the difference between the amount[A] of water to be added to the alcohol solution of the titaniumalkoxide and the amount [B] of water to be discharged out of thereaction system where the polymer is formed and deposited by the addingwater to the alcohol solution before the polymer separated from thealcohol solution is dissolved in the presence of the organic solvent isabout 1.5 to 1.95 moles per 1 mole of the titanium alkoxide. In otherwords, an amount of water substantially consumed during the hydrolysisreaction should be about 1.5 to 1.95 mole, and is preferably about 1.6to 1.90 mole, per 1 mole of the titanium alkoxide. When the amount [B]of water to be discharged out of the reaction system is large, theamount [A] of water to be added can be used more than usual so that theamount of water substantially consumed during the hydrolysis reaction isadjusted to be the said amount. When the difference [A-B] of the amountof water, i.e. amount of water consumed substantially during thehydrolysis reaction is smaller than 1.5 mole, the polymerization degreeof the resulting polymer is small and the amount of an organic componentin the polymer is relatively large. When the resulting polymer isdissolved in the presence of the organic solvent to obtain a spinningsolution and spinning is carried out by using the resulting solution,the mechanical strength of the resulting titania fiber is liable to belowered. On the other hand, when the difference [A-B] of amount of waterexceeds 1.95 mole, it tends to become difficult to dissolve theresulting polymer in the presence of the organic solvent.

In the production of the titania fiber of the present invention, whenthe amount of water to be added is suitable, the resulting polymer hashigh polymerization degree and contains a large amount oftitanium-oxygen-titanium bonds and relatively contains small amount ofthe organic component. The titania fiber obtained by spinning thispolymer has high mechanical strength.

In the production of the titania fiber of the present invention, wateris not directly added normally, but preferably added by a solutionprepared by previously diluting water with the same kind of an alcoholas that in which the titanium alokoxide is dissolved. A concentration ofwater in the alcohol solution, in which water is diluted, is preferablyabout 1 to 50% by weight e.g. 99-50% by weight of the selected alcohol.When water is directly added, the reaction partially proceeds in thereaction system and a polymer which is insoluble in the presence of theorganic solvent is sometimes deposited.

The temperature when water is added to the alcohol solution of thetitanium alkoxide and when the hydrolysis reaction and thepolymerization reaction of the titanium alkoxide are carried out is notspecifically limited, but may be within the range from 0° C. to aboiling point of the alcohol to be used. When a fast reaction rate isdesired, a high reaction temperature is preferable. The hydrolysis andpolymerization reaction may be carried out under reflux at the boilingpoint after the alcohol solution in which water is diluted is added at aroom temperature, e.g. about 25° C.

From the industrial point of view, a high concentration of titanium inthe reaction system is preferable. Therefore, a diluted solution ofwater with alcohol is preferably added to the alcohol solution of thetitanium alkoxide at a temperature of the boiling point of the alcoholin which the titanium alkoxide is dissolved, and is preferably addedwhile the alcohol is discharged out of the reaction system in the sameamount as that of the alcohol which is added with water to inhibit adecrease of concentration of titanium due to the addition of thesolution of water.

The polymer deposited in the alcohol solution by the hydrolysis andpolymerization reaction is dissolved in the presence of the organicsolvent, as it is in the suspended state or after partially orcompletely removing the alcohol, to form a spinning solution.

The method of partially or completely removing the alcohol from thealcohol suspension of the polymer is not particularly limited, andexamples thereof include methods by means of filtration, centrifugation,concentration with heating, concentration under reduced pressure and thelike. If necessary, drying may be conducted at this stage with heatingor under reduced pressure.

In the step of dissolving the polymer in the presence of the organicsolvent, preferably, all of the alcohol is substantially removed fromthe alcohol suspension of the polymer and the polymer is then dissolvedin the presence of the organic solvent. When the alcohol is partiallyremoved from the suspension and the polymer is dissolved in the presenceof the organic solvent, water contained in the suspension after thealcohol was partially removed is preferably removed from the reactionsystem before the polymer is dissolved. Various methods for removingwater from the alcohol suspension are suitable, such as removing thealcohol and water simultaneously under heating and/or reduced pressureafter adding the alcohol containing no water to the suspension.

The organic solvent which is used for dissolving the polymer is notlimited as long as the polymer can be dissolved therein. Suitableorganic solvents are ethers, aromatic hydrocarbons and the like. Sincethe organic solvent is a main solvent in the spinning solution and itsboiling point effects the properties of a precursor fiber, an organicsolvent whose boiling point is from about 40° C. to about 120° C. ispreferably used. Examples of the preferable organic solvent includetetarhydrofuran, diethyl ether, toluene and the like. A high-boilingpoint solvent is not preferable.

The amount of the organic solvent to be used in the solution in whichthe polymer is dissolved is preferably about 25 to about 90% by weight,and is more preferably about 50 to about 80% by weight based on thesolvents consisting essentially of the said alcohol, the said compoundhaving active hydrogen and the said organic solvent.

The polymer concentration in the solution in which the polymer isdissolved is preferably from about 50 to about 80% by weight based onthe solution. When the polymer concentration is lower than this range,the concentration may be adjusted by removing the organic solvent underheating an/or reduced pressure to concentrate the solution to within theabove range. The spinning solution is obtained by way of adjusting thepolymer concentration to within the desired concentration range. Whenspinning is conducted, a viscosity of the spinning solution is alsoadjusted and controlled. A suitable viscosity of the spinning solutionis within the range from about 10 to about 2000 poise, and is preferablyfrom about 20 to about 500 poise. This viscosity can be controlled byadjusting the concentration of the polymer and/or adjusting atemperature of the spinning solution.

The precursor fiber can be obtained by using this spinning solutionwhose polymer concentration and viscosity were adjusted. The method ofspinning is not limited and, for example, known spinning method such asnozzle extrusion spinning, centrifugal spinning, blow spinning, etc. canbe applied. When spinning is conducted, the precursor fiber can also bestretched by using a rotating roller, a high-speed air current and thelike. It is preferable to select a proper spinning atmosphere and toadjust the temperature and the humidity of the blowing air in order toobtain a desired fiber.

The above-mentioned method comprising steps of adding water to thealcohol solution of the titanium alkoxide to form a polymer due to thehydrolysis and polymerization reaction, optionally separating thepolymer from the alcohol solution and dissolving the resulting polymerin the presence of the organic solvent to produce a spinning solutioncan be carried out not only by a batch but also by a continuous method.

The precursor fiber obtained by spinning is calcined after subjecting itto an optional pretreatment such as a water vapor treatment, athermohydro treatment, an acid treatment or a treatment in combinationthereof.

The above pretreatment is particularly essential to obtain the poroustitania fiber of the present invention, i.e. continuous fiber of titaniahaving physical properties wherein an average diameter per amonofilament is from 5 to 50 μm, a BET specific surface area is 10 m² /gor more, a pore volume is 0.05 cc/g or more, a volume of pores having apore diameter of not less than 10 angstroms is 0.02 cc/g or more and anaverage tensile strength per a monofilament is 0.1 GPa or more. Thewater vapor treatment includes treating the precursor fiber obtained byspinning with water vapor at a temperature of about 80 to about 300° C.under an atmosphere having a water vapor partial pressure of about 0.3atm or more, preferably from about 0.3 to about 20 atm for not less than0.5 hours, preferably from about 1 to about 24 hours. The higher thetemperature and/or the water vapor partial pressure of the water vaportreatment is, the shorter the required treating time becomes. When thetreating temperature is lower than about 80° C., a long-time treatmentis required even if the water vapor partial pressure is high and it isnot preferable, industrially. When the water vapor partial pressure isless about 0.3 atm, a long-time treatment is required.

In the present invention, the water vapor treatment of the precursorfiber is normally conducted before calcination. But when the aboveconditions of temperature, water vapor partial pressure and treatingtime can be applied, the water vapor treatment can be incorporated intothe calcination step and can be carried out during calcination.

In the method for producing the porous titania fiber of the presentinvention, the reason why a porous titania fiber having a large porevolume can be obtained by the pretreatment like the water vaportreatment, but is considered as follows. That is, since the precursorfiber obtained by spinning contains an organic component derived from anorganic group of a solvent and a polymer side chain, when the precursorfiber is subjected to the pretreatment like the water vapor treatment,the polymer in the fiber is further hydrolyzed and the organic componentof the side chain comes off to change into an OH group and, furthermore,a number of a --Ti--O--Ti-- bond increases due to the polymerizationreaction. When the organic component comes off and the --Ti--O--Ti--bond is formed, a lot of pores are formed in the fiber and the size ofthe pores is comparatively large. Therefore, the pores are remained inthe calcination step, which results in porous fiber.

Almost all of the organic component in the precursor fiber comes off at300° C. or less in the calcination step. Accordingly, the water vaportreatment is preferably carried out at a temperature of about 300° C. orless, e.g. about 80 to about 300° C., and is more preferably about 80 toabout 200° C.

In the present invention, a porous titania fiber having high mechanicalstrength can be produced by adding water to an alcohol solution of atitanium alkoxide to carry out a hydrolysis reaction and apolymerization reaction of the titanium alkoxide, dissolving theresulting polymer in the presence of the organic solvent, spinning byusing the resulting polymer-in-organic solvent solution as a spinningsolution, subjecting the resulting precursor fiber to a pretreatmentsuch as a water vapor treatment, followed by calcination, and when atitania fiber having higher mechanical strength is required, a siliconcompound may be included in the spinning solution.

The silicon compound is not limited as long as it can be uniformly mixedand dispersed in the spinning solution. The silicon compound ispreferably an alkyl silicate represented by the general formula [3]:

    Si.sub.n O.sub.n-1 (OR.sup.3).sub.2n+2                     [ 3]

wherein R³ represents an alkyl group having 1 to 4 carbon atoms, and nrepresents an integer of 1 or more. Each of R³ in the formula [3] can bedifferent from one another. A particularly preferable alkyl silicate isan ethyl silicate of the general formula [3] wherein R³ is an ethylgroup and n is 4 to 6.

The amount of the silicon compound to be used is preferably equivalentto the amount wherein the silica content in the titania fiber obtainedafter calcination is from about 1 to 40% by weight, and is morepreferably form about 5 to about 30% by weight, based on the fiber. Whenthe silica content exceeds 40% by weight based on the fiber, themechanical strength of the resulting titania fiber is not increased andthe content of the titania component is relatively decreased. Therefore,when using the titania fiber whose silica content exceeds 40% as acatalyst carrier, the catalytic activity is liable to be deteriorated,unfavorably.

When the silicon compound is used for producing the continuous fiber oftitania of the present invention, it is contained in the spinningsolution before spinning. Examples of the method of containing thesilicon compound includes a method of containing a silicon compound inan alcohol solution of a titanium alkoxide or in an alcohol solution ofthe titanium alkoxide and a compound having active hydrogen, and amethod of containing a silicon compound in the organic solvent solutionof the polymer on and/or after dissolving the polymer obtained by thehydrolysis and the polymerization reaction of the titanium alkoxide inthe presence of the organic solvent and the like.

In the production of the continuous fiber of titania of the presentinvention, the precursor fiber obtained by spinning is calcined aftersubjecting it to an optional pretreatment such as a water vaportreatment.

The calcination method is not specifically limited, and includes amethod of calcining in air and the like. The titania fiber obtained bycalcination may be optionally calcined again. During the calcination, atension may be applied to the precursor fiber and/or titania fiber.

The calcination temperature is not specifically limited, and ispreferably within the range from about 500 to about 1100° C. When thecalcination temperature is lower than about 500° C., the resulting fiberis porous but the mechanical strength tends to decrease. On the otherhand, when it is higher than about 1100° C., the porosity tends todecrease. As described, the higher the calcination temperature is, themore the porosity tends to decrease, that is, the more the BET specificsurface area and pore volume tend to be small. However, when theprecursor fiber obtained by spinning is subjected to a water vaportreatment at high temperature under an atmosphere of high water vaporpartial pressure for a long time, the porosity can be maintained even ifit is calcined at high temperature.

As the calcination temperature becomes higher, the titania fiber ischanged from an amorphous fiber into a fiber of an anatase-form crystal,then into a fiber of a rutile-form crystal during the calcination. Acrystallization temperature and a transition temperature at which theanatase-form crystal is changed into the rutile-form crystal varydepending on the silica content in the fiber. Accordingly, a titaniafiber having a desired crystal form can be obtained by controlling thecalcination temperature and the silica content. For example, regarding atitania fiber containing no silica, a fiber having an anatase-formcrystal can be obtained by calcination at 600° C., and a fiber having arutile-form crystal can be obtained by calcination at 900° C.,respectively. Regarding a titania fiber whose silica content is about15% by weight based on the fiber, a fiber having an anatase-form crystalcan be obtained by calcination at 900° C., and a fiber having arutile-form crystal can be obtained by calcination at 1100° C.,respectively.

Using the above method, according to the method of the presentinvention, a continuous fiber of titania containing an anatase-formtitanium oxide as a main component, which constitutes at least 50% ofthe whole content of a crystal, can be obtained. A titania fiber of arutile-form titanium oxide and a mixture of an anatase-form titaniumoxide and a rutile-form titanium oxide can be obtained, as well. Everytitania fiber has number of advantages and can be used for variouspurposes. When a titania fiber is used as a catalyst, however, a titaniafiber of an anarase-form crystal is preferable in view of the catalyticactivity.

The porous titania fiber obtained by the above method exhibits excellentcharacteristics, and particularly so with respect to a catalyst and acatalyst carrier applications.

The titania fiber obtained by the present invention is a continuousfiber in the form of a long fiber, and the fiber is applied to varioususes after forming into a short fiber by cutting into a suitable length,if necessary.

The catalyst component-carrying titania fiber of the present inventioncan be obtained by carrying the catalyst component on and/or in thetitania fiber.

The preferred catalyst component will differ depending on the use.Examples of the catalyst component include a metal, an oxide of a metal,or a complex oxide of a metal, wherein the metal is from Group II a, IVa, V a, VI a, VIII,III b or V b of the Periodic Table of Elements.Representative metals include those selected from the group consistingof V, W, Al, As, Ni, Zr, Mo, Ru, Mg, Ca and Pt. The continuous fiber oftitania of the present invention can support not only one kind ofcatalyst component but also two or more kinds of components at once. Ametal selected from the group consisting of V, W, Mo, an oxide of anythereof and a complex oxide of any thereof are preferable for use ascatalyst components of the catalyst for reduction of nitrogen oxide.

The method for producing the catalyst component-carrying titania fiberis not specifically limited and, for example, there is a methodcomprising the combination of steps of immersing a continuous fiber oftitania of the present invention in a solution containing a catalystcomponent with or without evacuating to permeate the solution positivelyinto pores of the fiber, removing the fiber, drying the fiber andcalcining the fiber. The optimum calcination temperature will differdepending on the use, i.e. kind of the catalytic reaction, reactiontemperature, etc., and is not specifically limited. For example, it isfrom about 200 to about 1000° C. In the case of using some catalystcomponents, the calcination at high temperature may cause deteriorationof the catalytic activity due to sintering of catalyst particles.Therefore, the calcination temperature may be appropriately decidedaccording to the kind of the catalyst component.

Regarding the catalyst component-carrying titania fiber of the presentinvention, an optimum amount of the catalyst component to be carriedbased on the titania fiber will differ depending on the kind of use,i.e. the catalytic reaction, and it is generally from about 0.5 to about50% by weight in terms of a metal, an oxide of any thereof and a complexoxide of any thereof, base on the titania fiber. When the fiber is usedas a catalyst for reduction of a nitrogen oxide, the amount ispreferably from about 0.5 to about 30% by weight based on the titaniafiber. When the amount is less than about 0.5% by weight, the activesurface area of the fiber tends to become small and the catalyticactivity tends not to be sufficient. When the amount is larger thanabout 50% by weight, quite a large amount of the catalyst component iscarried at the various positions, e.g. not only inside of the fiber butalso the outer surface of the fiber and, therefore, the catalystcomponent tends to come off and the active surface area tends not toincrease any more, and it is unfavorable in view of the cost.

As described above in detail, according to the present invention, acontinuous fiber of titania having excellent spinning stability and highmechanical strength can be obtained by an industrially easy specificproduction method and, furthermore, a continuous fiber of titania havinga remarkably large specific surface area and a remarkably large porevolume, which is excellent as a catalyst and a catalyst carrier, can beobtained by subjecting the precursor fiber obtained in the said methodto a water vapor treatment before calcination and/or during calcination.Also, according to the present invention, a catalyst component-carryingtitania fiber having a large active surface area and a large pore volumecan be obtained, wherein catalyst component thereof hardly comes off andhigh activity thereof can be maintained for a long period of time.Accordingly, the industrial utilization value of the titania fiber andcatalyst component-carrying titania fiber of the present invention isremarkably large, especially they are used as the catalyst for reductionof a nitrogen oxide, oxidation of an organic compound, e.g. theoxidation of benzene to obtain maleic anhydride, and the like.

Continuous fibers of titania, catalyst component-carrying titania fiberstherefrom, the methods of preparing both of the foregoing and themethods of using both of the foregoing of the present invention aredescribed in Japanese application nos. 08-348930, filed Dec. 26, 1996,09-073713, filed Mar. 26, 1997, and 09-109627, filed Apr. 25, 1997, thecomplete disclosures of which are incorporated herein by reference.

EXAMPLES

The following non-limiting Examples and Comparative Examples furtherillustrate the present invention in detail.

In the Examples and Comparative Examples, the measurement of aconcentration of water in alcohol, an average diameter per amonofilament, an average tensile strength per a monofilament, a crystalform of the fiber, a BET specific surface area, a pore volume, SEMobservation and EPMA analysis were conducted in the following manners.

Concentration of water in alcohol: The concentration of water in asample was measured by using a Karl Fischer moisture content meter(Model MKS-210, manufactured by Kyoto Denshi Co., Ltd.)

Average diameter: A fiber was observed by using an optical microscopeand twenty monofilaments observed in the field of view of the fiber wereselected at random to be measured. A fiber diameter of each monofilamentwas measured and the average value thereof was taken as the averagediameter per a monofilament of the filber.

Average tensile strength: Using an automatic monofirament tensile tester(control section: Model AMF-C, tensile device section: TENSILON, ModelUTM-2-20, manufactured by Toyo Boldwin Co., Ltd.), a tensile test of amonofilament was conducted under the conditions of a length of themonofilament of 25 mm and a stress rate of 1 mm/min. A strength at whicha monofilament is broken was measured, and the average value of thirtymeasurements was taken as the average tensile strength per amonofilament of the fiber.

Crystal form: A fiber was slightly ground in a mortar and then analyzedby using a X-ray diffractmeter (Model RAD-IIA, manufactured by RigakuDenki Co., Ltd.) to observe the crystal form of the fiber.

BET specific surface area: A fiber was slightly ground in a mortar, andthen a BET specific surface area was measured by using MicrometricsFLOWSORB-II Model 2300 (manufactured by Shimadzu Corporation).

Pore volume: A fiber was slightly ground in a mortar, and then a porevolume was measured with a nitrogen gas by using a gasadsorption/desorption analyser OMUNISOAP Model 360 (manufactured byCOULTER Co.).

SEM observation: A fiber was mounted on a specimen carrier and, aftergold deposition was conducted by using an ion sputtering device (ModelJFC-1100E, manufactured by Nippon Denshi Co., Ltd.), the fiber surfaceand fractured surface of the cross section were observed by a scanningelectron microscope (Model JSM-T300, manufactured by Nippon Denshi Co.,Ltd.).

EPMA analysis: A fiber was embedded in a room temperature-type curingresin and, after curing, the embedded fiber was cut and elementalanalysis of the fractured surface was conduct by an electron probemicroanalyser (Model EPM-810, manufactured by Shimadzu Corporation).

Example 1

Titanium isopropoxide (1st grade reagent, manufactured by Wako PurePharmaceuticals Co., Ltd.) (300.0 g) and ethyl acetoacetate (extra purereagent, manufactured by Wako Pure Pharmaceuticals Co., Ltd.) (54.9 g)were dissolved in isopropyl alcohol (extra pure reagent, manufactured byWako Pure Pharmaceuticals Co., Ltd.) (700.0 g) and the solution wasrefluxed under a nitrogen atmosphere for 1 hour to prepare an alcoholsolution of titanium isopropoxide. At this time, a molar ratio of ethylacetoacetate to titanium isopropoxide is 0.40. Separately, pure water(51.0 g) was mixed with isopropyl alcohol (460.2 g) to prepare analcohol solution having a water concentration of 10% by weight. Anamount of water in the solution is 2.7 mole ratio based on titaniumisopropoxide used.

The alcohol solution of titanium isopropoxide was heated in a nitrogenatmosphere and refluxed under boiling and the alcohol solution of waterwas added into the solution of titanium isopropoxide with distilling thealcohol under stirring. A distillation rate of the alcohol was adjustedto a rate which is almost the same as an addition rate of the alcoholsolution of water. An addition period of time of the alcohol solution ofwater was adjusted to 135 min.

The deposition of a polymer started when an amount of added water was2.1 mole per 1 mole of used titanium isopropoxide. Once the totalselected amount of water was added, the solution was in a slurry state.The amount of water in the distilled alcohol was 0.29 mole per 1 mole oftitanium isopropoxide used.

After the slurry was refluxed for 1 hour, the alcohol in the slurry wasdistilled with heating and a polymer was dried by continuously heatingwith an oil bath at 143° C. until the alcohol can not be distilled. Thepolymer after drying was a yellow powder and the weight was 144 g. Theamount of water in the distilled alcohol was 0.61 mole per 1 mole oftitanium isopropoxide used. Accordingly, a difference between the amountof water added and the amount of water discharged together with thealcohol out of the reaction system was 1.8 mole [=2.7-(0.29+0.61)] per 1mole of titanium isopropoxide used.

Then, the polymer was dissolved in tetrahydrofuran (extra pure reagent,manufactured by Wako Pure Pharmaceuticals Co., Ltd.) (460 g) and ethylsilicate 40 (manufactured by Tama Kagaku Kogyo Co., Ltd.) (37.2 g) wasadded into the tetrahydrofuran solution and the solution was refluxedfor 1 hour. The said amount of ethyl silicate added is equivalent to theamount wherein the silica content in the titania fiber which is obtainedafter spinning, a water vapor treatment and calcination is 15% by weightbased on the fiber.

After the tetrahydrofuran solution of the polymer was filtered through aTeflon membrane filter having a pore diameter of 3 μm, the filtrate wasconcentrated by distilling tetrahydrofuran with heating to obtain 200 gof a spinning solution. A viscosity of the spinning solution was 50poise at 40° C.

The spinning solution at 40° C. was extruded into an air atmosphere (40°C., relative humidity (RH): 60%) through a nozzle having a diameter of50 μm with a nitrogen gas under a pressure of 20 kg/cm², followed byhauling off at a haul-off rate of 70 m/min to obtain a precursor fiber.

The resulting precursor fiber was put in a thermo-hygrostat (70° C., RH:70%) and treated with water vapor for 30 min. After the temperature wasraised at a rate of 200° C./hour, the precursor fiber was calcined at900° C. for 30 min to obtain a titania fiber.

The resulting titania fiber had an average diameter of 15 μm per amonofilament and a high average tensile strength of 1.4 Gpa per amonofilament. According to the X-ray diffraction (XRD) analysis, thefiber was an anatase-form titanium oxide and only a peak of ananatase-form crystal was recognized.

Example 2

According to the same manner as that described in Example 1 except forchanging the calcination temperature after the water vapor treatment to1100° C., a titania fiber was obtained.

The resulting titania fiber had an average diameter of 15 μm per amonofilament and a high average tensile strength of 1.1 Gpa per amonofilament. According to the XRD analysis, the fiber was rutile-formtitanium oxide and only a peak of a rutile-form crystal was recognized.

Example 3

Titanium isopropoxide (300.0 g) and ethyl acetoacetate (54.9 g) weredissolved in isopropyl alcohol (128.6 g) and the solution was refluxedunder a nitrogen atmosphere for 1 hour to prepare an alcohol solution oftitanium isopropoxide. Separately, pure water (51.0 g) was mixed withisopropyl alcohol (1653.3 g) to prepare an alcohol solution having awater concentration of 3% by weight.

The alcohol solution of titanium isopropoxide was heated in a nitrogenatmosphere and refluxed under boiling and the alcohol solution of waterwas added into the solution of titanium isopropoxide with distilling thealcohol under stirring. A distillation rate of the alcohol was adjustedto a rate which is almost the same as an addition rate of the alcoholsolution of water. An addition period of time of the alcohol solution ofwater was adjusted to 140 min. When the total amount of water was added,the solution was in slurry state.

After the slurry was refluxed for 1 hour, the alcohol in the slurry wasdistilled with heating and a polymer was dried by continuously heatingwith an oil bath at 143° C. until the alcohol can not be distilled.According to the same manner as that described in Example 1, the amountof water discharged out of the reaction system was measured. As aresult, a difference between the amount of water added and the amount ofwater discharged out of the reaction system was 1.78 mole per 1 mole oftitanium isopropoxide used.

Using the polymer after drying, according to the same manner as thatdescribed in Example 1, dissolution in tetrahydrofuran, addition ofethyl silicate, reflux, filtration and concentration were conducted toobtain a spinning solution. The spinning, the water vapor treatment andcalcination were carried out to obtain a titania fiber, as in Example 1.

Physical properties of the titania fiber thus obtained were examined. Asa result, the crystal form of the fiber was an anatase and, furthermore,an the average diameter was 16 μm per a monofilament and the averagetensile strength was 1.2 Gpa per a monofilament.

Example 4

According to the same manner as that described in Example 1, the alcoholsolution of titanium isopropoxide and alcohol solution of water having awater concentration of 10% by weight were prepared to obtain a slurry ofa polymer.

The slurry was concentrated by using an oil bath at 80° C. and anevaporator and further vacuum-dried to obtain a polymer powder.

After the polymer powder was dissolved in tetrahydrofuran (270 g), ethylsilicate 40 (37.2 g) was added into the tetrahydrofuran solution and thesolution was refluxed. According to the same manner as that described inExample 1, the solution was filtered and the filtrate was concentratedto prepare a spinning solution and then the polymer was spun by usingthe spinning solution to obtain a precursor fiber. According to the samemanner as that described in Example 1, the precursor fiber was treatedwith water vapor and then calcined to obtain a titania fiber.

In this method, a difference between the amount of water added and theamount of water discharged out of the reaction system was 1.72 mole per1 mole of titanium isopropoxide used. The crystal form of the resultingtitania fiber was an anatase and, furthermore, the average diameter was16 μm per a monofilament and the average tensile strength was 1.3 Gpaper a monofilament.

Example 5

Titanium isopropoxide (300.0 g) and ethyl acetoacetate (54.9 g) weredissolved in isopropyl alcohol (73.6 g) and the solution was refluxedunder a nitrogen atmosphere for 1 hour to prepare an alcohol solution oftitanium isopropoxide. Separately, pure water (34.2 g) was mixed withisopropyl alcohol (79.8 g) to prepare an alcohol solution having a waterconcentration of 30% by weight. The amount of water is 1.8 mole per 1mole of titanium isopropoxide used.

The alcohol solution of titanium isopropoxide was cooled in a nitrogenatmosphere to 10° C. and the above alcohol solution of water was addedinto the solution of titanium isopropoxide under stirring. The additionperiod of time was adjusted to be 45 min.

When the total amount of water was added, the solution was transparent.Deposition of the polymer was started by heating. On reaching the refluxtemperature, the solution was in slurry state.

After the slurry was refluxed for 1 hour, the alcohol was distilled withheating and a polymer was dried by continuously heating with an oil bathat 120° C. until the alcohol can not be distilled.

Then, the polymer powder was dissolved in tetrahydrofuran (270 g) andethyl silicate 40 (37.2 g) was added into the tetrahydrofuran solutionand the solution was refluxed for 1 hour. According to the same manneras that described in Example 1, the solution was filtered and thefiltrate was concentrated to prepare a spinning solution and the polymerwas spun by using the spinning solution to obtain a precursor fiber.According to the same manner as that described in Example 1, theprecursor fiber was treated with water vapor and then calcined to obtaina titania fiber.

In this method, a difference between the amount of water added and theamount of water discharged out of the reaction system was 1.69 mole per1 mole of titanium isopropoxide used. The crystal form of the resultingtitania fiber was an anatase and, furthermore, the average diameter was15 μm per a monofilament and the average tensile strength was 0.9 Gpaper a monofilament.

Example 6

Titanium isopropoxide (300.0 g) and ethyl acetoacetate (68.7 g) weredissolved in isopropyl alcohol (700.0 g) and the solution was refluxedunder a nitrogen atmosphere for 1 hour to prepare an alcohol solution oftitanium isopropoxide. At this time, a molar ratio of ethyl acetoacetateto titanium isopropoxide is 0.50. Separately, pure water (56.4 g) wasmixed with isopropyl alcohol (1837.8 g) to prepare an alcohol solutionhaving a water concentration of 3% by weight. The amount of water is 3.0mole per 1 mole of titanium isopropoxide used.

The alcohol solution of titanium isopropoxide was heated and refluxedunder boiling in a nitrogen atmosphere and, at the same time, an alcoholsolution having a water concentration of 3% by weight was added into thesolution of the titanium isopropoxide under stirring with distilling thealcohol. The distillation rate of the alcohol was adjusted to a ratewhich is almost the same as an addition rate of the alcohol solution ofwater, and the addition period of time was 160 min. When the totalamount of water was added, the solution was in slurry state.

After the slurry was refluxed for 1 hour, the alcohol was distilled withheating to obtain 305 g of a concentrated slurry.

Then, the concentrated slurry was dissolved in tetrahydrofuran (460 g)and ethyl silicate 40 (37.2 g) was added into the tetrahydrofuransolution and the solution was refluxed for 1 hour. According to the samemanner as that described in Example 1, a spinning solution was prepared.According to the same manner as that described in Example 1, the polymerwas spun by using the spinning solution, followed by the water vaportreatment and calcination to obtain a titania fiber.

In this method, a difference between the amount of water added and theamount of water discharged out of the reaction system was 1.84 mole per1 mole of titanium isopropoxide used. The crystal form of the resultingtitania fiber was an anatase and, furthermore, the average diameter was16 μm per a monofilament and the average tensile strength was 1.1 Gpaper a monofilament.

Example 7

Titanium isopropoxide (300.0 g) and ethyl acetoacetate (54.9 g) weredissolved in isopropyl alcohol (700.0 g) and the solution was refluxedunder a nitrogen atmosphere for 1 hour to prepare an alcohol solution oftitanium isopropoxide. To the alcohol solution, ethyl silicate 40 (37.2g) was added, and the solution was further refluxed for 1 hour.

Separately, pure water (51.0 g) was mixed with isopropyl alcohol (460.2g) to prepare an alcohol solution having a water concentration of 10% byweight. The alcohol solution of titanium isopropoxide was heated andrefluxed under boiling in a nitrogen atmosphere and, at the same time,an alcohol solution having a water concentration of 10% by weight wasadded into the solution of the titanium isopropoxide under stirring withdistilling the alcohol. When the total amount of water was added, thesolution was in slurry state.

After the slurry was refluxed for 1 hour, the alcohol was distilled withheating. Furthermore, the slurry was continuously heated with an oilbath at 143° C. until the distilled solution can not be obtained to drythe polymer.

The polymer was dissolved in tetrahydrofuran (270 g) with heating and,according to the same manner as that described in Example 1, thesolution was filtered and concentrated to prepare a spinning solutionand then the polymer was spun by using the spinning solution to obtain aprecursor fiber. According to the same manner as that described inExample 1, the precursor fiber was treated with water vapor and thencalcined to obtain a titania fiber.

In this method, a difference between the amount of water added and theamount of water discharged out of the reaction system was 1.83 mole per1 mole of titanium isopropoxide used. The crystal form of the resultingtitania fiber was an anatase and, furthermore, the average fiberdiameter was 15 μm per a monofilament and the average tensile strengthwas 0.9 Gpa per a monofilament.

Example 8

Titanium isopropoxide (300.0 g) and ethyl acetoacetate (13.7 g) weredissolved in isopropyl alcohol (700.0 g) and the solution was refluxedunder a nitrogen atmosphere for 1 hour to prepare an alcohol solution ofa titanium isopropoxide. At this time, a molar ratio of ethylacetoacetate to titanium isopropoxide is 0.10. Separately, pure water(46.9 g) was mixed with isopropyl alcohol (1530.5 g) to prepare analcohol solution having a water concentration of 3% by weight. Theamount of water is 2.5 mole per 1 mole of titanium alkoxide used.

The alcohol solution of titanium isopropoxide was heated in a nitrogenatmosphere and refluxed under boiling and the alcohol solution of waterwas added into solution of titanium isopropoxide with distilling thealcohol under stirring. When the total amount of water was added, thesolution was in slurry state.

After the slurry was refluxed for 1 hour, the alcohol was distilled withheating. Furthermore, the slurry was continuously heated with an oilbath at 143° C. until the distilled solution can not be obtained to drythe polymer.

After the polymer powder was dissolved in tetrahydrofuran (460 g), ethylsilicate 40 (37.2 g) was added into the tetrahydrofuran solution and thesolution was refluxed for 1 hour. According to the same manner as thatdescribed in Example 1, the solution was filtered and concentrated toprepare a spinning solution and then the polymer was spun by using thespinning solution to obtain a precursor fiber. According to the samemanner as that described in Example 1, the precursor fiber was treatedwith water vapor and then calcined to obtain a titania fiber.

In this method, a difference between the amount of water added and theamount of water discharged out of the reaction system was 1.67 mole per1 mole of titanium isopropoxide used. The crystal form of the resultingtitania fiber was an anatase and, furthermore, the average diameter was16 μm per a monofilament and the average tensile strength was 1.0 Gpa.

Example 9

Titanium isopropoxide (300.0 g) and ethyl acetoacetate (24.7 g) weredissolved in isopropyl alcohol (700.0 g) and the solution was refluxedunder a nitrogen atmosphere for 1 hour to prepare an alcohol solution ofa titanium isopropoxide. At this time, a molar ratio of ethylacetoacetate to titanium isopropoxide is 0.18. Separately, pure water(46.9 g) was mixed with isopropyl alcohol (1530.5 g) to prepare analcohol solution having a water concentration of 3% by weight. Theamount of water is 2.5 mole per 1 mole of titanium alkoxide used.

The alcohol solution of titanium isopropoxide was heated in a nitrogenatmosphere and refluxed under boiling and the alcohol solution of waterwas added into solution of titanium isopropoxide with distilling thealcohol under stirring. When the total amount of water was added, thesolution was in slurry state.

After the slurry was refluxed for 1 hour, the alcohol was distilled withheating. Furthermore, the slurry was continuously heated in an oil bathat 143° C. until the distilled solution can not be obtained to dry thepolymer.

The polymer was dissolved in tetrahydrofuran (460 g) with heating and,after filtering through a Teflon membrane filter having a pore diameterof 3 μm, tetrahydrofuran was distilled by heating to obtain a spinningsolution. According to the same manner as that described in Example 1except for using this spinning solution and changing the calcinationtemperature to 600° C., a spinning, a water vapor treatment andcalcination were conducted to obtain a titania fiber.

In this method, a difference between the amount of water added and theamount of water discharged out of the reaction system was 1.69 mole per1 mole of titanium isopropoxide used. The crystal form of the resultingtitania fiber was an anatase and, furthermore, the average diameter was17 μm per a monofilament and the average tensile strength was 0.8 Gpaper a monofilament.

Example 10

According to the same manner as that described in Example 9 except forchanging the calcination conditions from 600° C.×30 min to 900° C.×30min, a titania fiber was obtained.

In this method, the crystal form of the resulting fiber was a rutileand, furthermore, the average diameter was 17 μm per a monofilament andthe average tensile strength was 0.7 Gpa per a monofilament.

Example 11

According to the same manner as that described in Example 8 except forchanging the amount of ethyl acetoacetate to 34.4 g (molar ratio ofethyl acetoacetate to titanium isopropoxide is 0.25) and changing theamount of ethyl silicate 40 to 90.4 g (this amount of ethyl silicate isequivalent to an amount wherein the silica content in the titania fiberto be obtained is 30% by weight based on the fiber.

In this method, a difference between the amount of water added and theamount of water discharged out of the reaction system was 1.68 mole per1 mole of titanium isopropoxide used. The crystal form of the resultingfiber was an anatase and, furthermore, the average diameter was 15 μmper a monofilament and the average tensile strength was 0.9 Gpa per amonofilament.

Example 12

According to the same manner as that described in Example 8 except forchanging the amount of ethyl acetoacetate to 137.3 g (molar ratio ofethyl acetoacetate to titanium isopropoxide is 1.00), a titania fiberwas obtained.

In this method, a difference between the amount of water added and theamount of water discharged out of the reaction system was 1.76 mole per1 mole of titanium isopropoxide used. The crystal form of the resultingfiber was an anatase and, furthermore, the average diameter was 15 μmper a monofilament and the average tensile strength was 0.8 Gpa per amonofilament.

Example 13

Titanium isopropoxide (200.0 g) was dissolved in isopropyl alcohol(371.4 g) to prepare an alcohol solution of titanium isopropoxide.Separately, pure water (33.8 g) was mixed with isopropyl alcohol (1103.0g) to prepare an alcohol solution having a water concentration of 3% byweight. The amount of water is 2.7 mole per 1 mole of titanium alkoxideused.

The alcohol solution of titanium isopropoxide was heated in a nitrogenatmosphere and refluxed under boiling and the alcohol solution of waterwas added into solution of titanium isopropoxide with distilling thealcohol under stirring. When the total amount of water was added, thesolution was in slurry state. After the slurry was refluxed for 1 hour,the alcohol was distilled with heating. Furthermore, the slurry wascontinuously heated with an oil bath at 130° C. until the distilledsolution can not be obtained to dry the polymer.

The polymer was dissolved in tetrahydrofuran (270 g) with heating andetyl silicate 40 (24.8 g) was added into the tetrahydrofuran solutionand the solution was refluxed for 1 hour. After filtering through aTeflon membrane filter having a pore diameter of 3 μm, tetrahydrofuranwas distilled by heating to obtain a spinning solution. Then, thepolymer was spun by using the spinning solution to obtain a precursorfiber. According to the same manner as that described in Example 1, theprecursor fiber was treated with water vapor and then calcined to obtaina titania fiber.

In this method, a difference between the amount of water added and theamount of water discharged out of the reaction system was 1.68 mole per1 mole of titanium isopropoxide used. The crystal form of the resultingtitania fiber was an anatase and, furthermore, the average diameter was16 μm per a monofilament and the average tensile strength was 1.0 Gpaper a monofilament.

Example 14

Titanium isopropoxide (200.0 g) and ethyl salicylate (extra purereagent, manufactured by Wako Pure Pharmaceuticals Co., Ltd.) (46.7 g)were dissolved in isopropyl alcohol (324.7 g) and the solution wasrefluxed under a nitrogen atmosphere for 1 hour to prepare an alcoholsolution of titanium isopropoxide. At this time, a molar ratio of ethylsalicylate to titanium isopropoxide is 0.40. Separately, pure water(31.5 g) was mixed with isopropyl alcohol (284.3 g) to prepare analcohol solution having a water concentration of 10% by weight. Theamount of water is 2.5 mole per 1 mole of titanium alkoxide used. Thealcohol solution of titanium isopropoxide was heated and refluxed underboiling in a nitrogen atmosphere and, at the same time, an alcoholsolution having a water concentration of 10% by weight was added intothe solution of the titanium isopropoxide under stirring with distillingthe alcohol. When the total amount of water was added, the solution wasin slurry state.

After the slurry was refluxed for 1 hour, the alcohol was distilled withheating. Furthermore, the slurry was continuously heated with an oilbath at 130° C. until the distilled solution can not be obtained to drythe polymer.

The polymer was dissolved in tetrahydrofuran (270 g) with heating andetyl silicate 40 (24.8 g) was added into the tetrahydrofuran solutionand the solution was refluxed for 1 hour. After filtering through aTeflon membrane filter having a pore diameter of 3 μm, tetrahydrofuranwas distilled by heating to obtain a spinning solution. Then the polymerwas spun by using the spinning solution to obtain a precursor fiber.According to the same manner as that described in Example 1, theprecursor fiber was treated with water vapor and then calcined to obtaina titania fiber.

In this method, a difference between the amount of water added and theamount of water discharged out of the reaction system was 1.75 mole per1 mole of titanium isopropoxide used. The crystal form of the resultingtitania fiber was an anatase and, furthermore, the average diameter was14 μm per a monofilament and the average tensile strength was 0.9 Gpaper a monofilament.

Example 15

Titanium isopropoxide (300.0 g) and ethyl acetoacetate (54.9 g) weredissolved in isopropyl alcohol (73.6 g) and the solution was refluxedunder a nitrogen atmosphere for 1 hour to prepare an alcohol solution oftitanium isopropoxide. At this time, a molar ratio of ethyl acetoacetateto titanium isopropoxide is 0.40. Separately, pure water (43.6 g) wasmixed with isopropyl alcohol (393.2 g) to prepare an alcohol solutionhaving a water concentration of 10% by weight. The amount of water is2.3 mole per 1 mole of titanium alkoxide.

The alcohol solution of titanium isopropoxide was heated in a nitrogenatmosphere and refluxed under boiling. At the same time, an alcoholsolution having a water concentration of 10% by weight was added intothe solution of titanium isopropoxide with distilling the alcohol understirring. The distillation rate of the alcohol was adjusted to a ratewhich is almost the same as the addition rate of the solution of water.The addition period of time was adjusted to 160 min. When the totalamount of water was added, the solution was in slurry state. The amountof water discharged out of the system by this operation was 0.20 moleper 1 mole of the titanium alkoxide used.

After the slurry was refluxed for 1 hour, the alcohol was distilled withheating to obtain 305 g of a concentrated slurry. The amount of waterdischarged out of the system by this operation was 0.17 mole per 1 moleof the titanium alkoxide used.

The alcohol was distilled by heating the concentrated slurry and, at thesame time, isopropyl alcohol (700 g) was added to remove water in theconcentrated slurry. The distillation rate was adjusted to a rate whichis the same as the addition rate of the alcohol. The addition period oftime was adjusted to 1.5 hours. The amount of water discharged out ofthe system by this operation was 0.24 mole per 1 mole of the titaniumalkoxide used. Accordingly, a difference between the amount of wateradded and the amount of water discharged together with the alcohol outof the reaction system was 1.69 mole [=2.3-(0.20+0.17+0.24)] per 1 moleof the titanium alkoxide.

After the dehydrated concentrated slurry was dissolved intetrahydrofuran (352 g), ethyl silicate 40 (37.2 g) was added and thesolution was refluxed for 1 hour. According to the same manner as thatdescribed in Example 1, the solution was filtered and concentrated toprepare a spinning solution and then the polymer was spun by using thespinning solution to obtain a precursor fiber. According to the samemanner as that described in Example 1, the precursor fiber was treatedwith water vapor and then calcined to obtain a titania fiber. Thecrystal form of the resulting fiber was an anatase and, furthermore, theaverage diameter was 15 μm per a monofilament and tensile strength was1.1 Gpa per a monofilament.

Example 16

According to the same manner as that described in Example 15 except forusing a nozzle having a diameter of 30 μm, a titania fiber was obtained.The crystal form of the resulting fiber was an anatase and, furthermore,the average diameter was 10 μm per a monofilament and the averagetensile strength was 1.3 Gpa per a monofilament.

COMPARATIVE EXAMPLE 1

Titanium isopropoxide (100.0 g) and ethyl acetoacetate (11.4 g) weredissolved in tetrahydrofuran (233.3 g) and the solution was refluxedunder a nitrogen atmosphere for 1 hour to prepare a tetrahydrofuransolution of titanium isopropoxide. At this time, a molar ratio of ethylacetoacetate to titanium isopropoxide is 0.25. Separately, pure water(10.7 g) was mixed with tetrahydrofuran (1781.7 g) to prepare atetrahydrofuran solution having a water concentration of 0.6% by weight.The amount of water is 1.7 mole per 1 mole of the titanium alkoxideused.

The tetrahydrofuran solution of titanium isopropoxide was heated andrefluxed under boiling in a nitrogen atmosphere and, at the same time,an tetrahydrofuran solution having a water concentration of 0.6% byweight was added into the solution of the titanium isopropoxide understirring with distilling the tetrahydrofuran. When the total amount ofwater was added, deposition of a polymer was not recognized and thesolution was transparent. Ethyl silicate 40 (12.4 g) was added to thissolution, and the solution was refluxed for 1 hour and then concentratedwith heating. As a result, a viscous solution having stringiness wasobtained. At this time, a viscosity of the solution was 50 poise at 40°C.

According to the same manner as that described in Example 1, spinningwas conducted by using the viscous solution to obtain a precursor fiber.According to the same manner as that described in Example 1, theprecursor fiber was treated with water vapor and then calcined to obtaina titania fiber. In this Comparative Example, a difference between theamount of water added and the amount of water discharged out of thesystem was 1.68 mole per 1 mole of titanium isopropoxide used. Thecrystal form of the resulting fiber was an anatase and, furthermore, theaverage diameter was 16 μm per a monofilament and the average tensilestrength was 0.4 Gpa per a monofilament.

COMPARATIVE EXAMPLE 2

Titanium isopropoxide (100.0 g) and ethyl acetoacetate (11.4 g) weredissolved in tetrahydrofuran (233.3 g) and the solution was refluxedunder a nitrogen atmosphere for 1 hour to prepare a tetrahydrofuransolution of titanium isopropoxide. At this time, a molar ratio of ethylacetoacetate to titanium isopropoxide is 0.25. Separately, pure water(11.3 g) was mixed with tetrahydrofuran (1886.6 g) to prepare atetrahydrofuran solution having a water concentration of 0.6% by weight.The amount of water is 1.8 mole per 1 mole of the titanium alkoxide.

The tetrahydrofuran solution of titanium isopropoxide was heated andrefluxed under boiling in a nitrogen atmosphere and, at the same time,an tetrahydrofuran solution having a water concentration of 0.6% byweight was added into the solution of the titanium isopropoxide understirring with distilling the tetrahydrofuran. When the total amount ofwater was added, deposition of a polymer was not recognized and thesolution was transparent. When this transparent solution was refluxedfor 1 hour, the solution was partially gelated and, finally, the wholesolution was solidified in the form of agar, thereby making itimpossible to prepare a spinning solution.

Example 17

The precursor fiber obtained by the same method as that described inExample 15 was put in a thermo-hygrostat (85° C., RH: 95%, water vaporpartial pressure: 0.54 atm) and treated with water vapor for 15 hours.Then, the precursor fiber was heated at a rate of 200° C./hour and wascalcined at 900° C. in air for 30 min to obtain a titania fiber.

The resulting titania fiber had an average diameter per a monofilamentof 16 μm and a BET specific surface area of 132 m² /g. The pore volumeby the nitrogen absorption method was 0.22 cc/g and the volume of poreshaving a pore diameter of not less than 10 angstroms was 0.22 cc/g. Theaverage tensile strength was 0.2 Gpa per a monofilament. According tothe XRD analysis, the fiber was an anatase titanium oxide and only apeak of anatase-form crystal was recognized.

Example 18

The precursor fiber which was obtained in the same method as in Example15 was put in a thermo-hygrostat (85° C., RH: 95%, water vapor partialpressure: 0.54 atm) and treated with water vapor for 5 hours. Then, theprecursor fiber was heated at a rate of 200° C./hour and was calcined at700° C. in air for 30 min to obtain a titania fiber.

The resulting titania fiber had an average diameter per a monofilamentof 16 μm and a BET specific surface area of 153 m² /g. The pore volumeby the nitrogen absorption method was 0.14 cc/g and the volume of poreshaving a pore diameter of not less than 10 angstroms was 0.66 cc/g. Theaverage tensile strength was 0.6 Gpa per a monofilament. According tothe XRD analysis, the fiber was an anatase-form titanium oxide.

Example 19

The precursor fiber which was obtained in the same method as in Example1 was put in a thermo-hygrostat (95° C., RH: 95%, water vapor partialpressure: 0.79 atm) and treated with a water vapor for 24 hours. Then,the precursor fiber was heated at a rate of 200° C./hour and wascalcined at 500° C. in air for 30 min to obtain a titania fiber.

The resulting titania fiber had an average diameter per a monofilamentof 17 μm and a BET specific surface area of 219 m² /g. The pore volumeby the nitrogen absorption method was 0.35 cc/g and the volume of poreshaving a pore diameter of not less than 10 angstroms was 0.24 cc/g. Theaverage tensile strength was 0.1 Gpa per a monofilament. According tothe XRD analysis, the fiber was an anatase-form titanium oxide.

Example 20

The precursor fiber which was obtained in the same method as in Example1 was put in a thermo-hygrostat (95° C., RH:95%, water vapor partialpressure: 0.79 atm) and treated with a water vapor for 24 hours. Then,the precursor fiber was heater at a rate of 200° C./hour and wascalcined at 900° C. in air for 30 min to obtain a titania fiber.

The resulting titania fiber had an average diameter per a monofilamentof 17 μm and a BET specific surface area of 104 m² /g. The pore volumeby the nitrogen absorption method was 0.21 cc/g and the volume of poreshaving a pore diameter of not less than 10 angstroms was 0.21 cc/g. Theaverage tensile strength was 0.2 Gpa per a monofilament. According tothe XRD analysis, the fiber was an anatase-form titanium oxide.

Example 21

The precursor fiber which was obtained in the same method as in Example15 was calcined in a tubular furnace. In this case, when the temperaturein the furnace reached 100° C., wet air having a water vapor partialpressure of 0.38 atm was fed into the tubular furnace by bubbling airinto water at 75° C. and the temperature in the furnace was maintainedat 150° C. for 2 hours. Then, the wet air was replaced by dry air, theprecursor fiber was calcined at 800° C. for 30 min to obtain a titaniafiber.

The resulting titania fiber had an average diameter per a monofilamentof 16 μm and a BET specific surface area of 66 m² /g. The pore volume bythe nitrogen absorption method was 0.12 cc/g and the volume of poreshaving a pore diameter of not less than 10 angstroms was 0.06 cc/g. Theaverage tensile strength was 0.7 Gpa per a monofilament. According tothe XRD analysis, the fiber was an anatase-form titanium oxide.

Example 22

The precursor fiber which was obtained in the same method as in Example1 was put in a thermo-hygrostat (85° C., RH: 95%, water vapor partialpressure: 0.54 atm) and treated with water vapor for 15 hours. Then, theprecursor fiber was heated at a rate of 200° C./hour was calcined at900° C. in air for 30 min to obtain a porous titania fiber.

The resulting titania fiber had an average diameter per a monofilamentof 16 μm and a BET specific surface area of 134 m² /g. The pore volumeby the nitrogen absorption method was 0.22 cc/g and the volume of poreshaving a pore diameter of not less than 10 angstroms was 0.22 cc/g. Theaverage tensile strength was 0.2 Gpa per a monofilament. According tothe XRD analysis, the fiber was an anatase-form titanium oxide and onlya peak of anatase-form crystal was recognized.

A vanadium oxide-carrying titania fiber to be used as a catalyst forcatalytic reduction of a nitrogen oxide was produced by the followingmethod.

An aqueous oxalic acid solution (0.5 mole/L) was prepared and ammoniummethavanadate was added to the aqueous solution to prepare a solution sothat the ammonium methavanadate content becomes 5% by weight. Thetitania fiber produces as described above was immersed in the resultingsolution, pulled up and then dried at 110° C. for 2 hours. After drying,the fiber was calcined at 400° C. for 1 hour to obtain a catalyst fiber,which is a catalyst component-carrying titania fiber.

The amount of vanadium oxide carried on and in the catalyst fiber was6.2% by weight based on the catalyst fiber. According to the SEMobservation, there was no vanadium oxide particles which were liable tocome off on the outer surface of the catalyst fiber, as shown in FIG. 1.According to the EPMA analysis, the fractured surface of the catalystfiber of the cross section was confirmed that the vanadium oxide wasuniformly carried in the catalyst fiber.

Then, catalyst performance test of the catalyst fiber as to reduction ofa nitrogen oxide was conducted as following.

After weighing 2 g of the catalyst fiber, the catalyst fiber was packedin a reaction tube having an inner diameter of 24 mm φ so that a packingheight becomes 2 cm. Then, a gas containing NO (100 ppm), NH₃ (100 ppm)and O₂ (10%) (200° C.) was passed through the reaction tube at a gasrate of 1 L/min. A nitrogen oxide removal efficiency was calculate withthe following formula. As a result, a nitrogen oxide removal efficiencywas 97%

Nitrogen oxide removal efficiency (%)=[(Y-X)/Y]×100

X: NO content in the gas which flowed out of the tube

Y: NO content in the gas which flowed into of the tube

Example 23

The precursor fiber which was obtained in the same method as in Example1 was put in a thermo-hygrostat (85° C., RH: 95%, water vapor partialpressure: 0.54 atm) and treated with water vapor for 5 hours. Then, theprecursor fiber was heated at a rate of 200° C./hour and was calcined at700° C. in air for 30 min to obtain a porous titania fiber.

The resulting titania fiber had an average diameter per a monofilamentof 16 μm and a BET specific surface area of 149 m² /g. The pore volumeby the nitrogen absorption method was 0.14 cc/g and the volume of poreshaving a pore diameter of not less than 10 angstroms was 0.06 cc/g. Theaverage tensile strength was 0.6 Gpa per a monofilament. According tothe XRD analysis, the fiber was an anatase-form titanium oxide.

Using the porous titania fiber, a catalyst fiber was prepared accordingto the same manner as that described in Example 22.An amount of thevanadium oxide carried on and in the catalyst fiber was 5.9% by widthbased on the catalyst fiber. According to SEM observation, there were novanadium oxide particles which were liable to come off on the outersurface of the catalyst fiber. According to the EPMA analysis, thefractured surface of the catalyst fiber of the cross section wasconfirmed that the vanadium oxide was uniformly carried in the catalystfiber in an amount of smaller than that in Example 22.

According to the same manner as that described in Example 22, a catalystperformance test was conducted. As a result, a nitrogen oxide removalefficiency was 72%.

Example 24

The precursor fiber which was obtained in the same method as in Example1 was put in a thermo-hygrostat (85° C., RH: 95%, water vapor partialpressure: 0.54 atm) and treated with water vapor for 10 hours. Then, theprecursor fiber was heated at a rate of 200° C./hour and was calcined at900° C. in air for 30 min to obtain a porous titania fiber.

The resulting titania fiber had an average diameter per a monofilamentof 15 μm and a BET specific surface area of 77 m² /g. The pore volume bythe nitrogen absorption method was 0.11 cc/g and the volume of poreshaving a pore diameter of not less than 10 angstroms was 0.11 cc/g. Theaverage tensile strength was 0.7 Gpa per a monofilament. According tothe XRD analysis, the fiber was an anatase-form titanium oxide.

Using the porous titania fiber, a catalyst fiber was prepared accordingto the same manner as that described in Example 22. An amount of thevanadium oxide carried on and in the catalyst fiber was 6.0% by weightbased on the catalyst fiber. According to the SEM observation, therewere no vanadium oxide particles which were liable to come off on theouter surface of the catalyst fiber. According to the EPMA analysis, thefractured surface of the catalyst fiber of the cross section wasconfirmed that the vanadium oxide was uniformly carried in the catalystfiber in an amount which is intermediate between the amount of Example22 and that of Example 23.

According to the same manner as that described in Example 22, a catalystperformance test was conducted. As a result, a nitrogen oxide removalefficiency was 92%.

COMPARATIVE EXAMPLE 3

The precursor fiber which was obtained in the same method as in Example1 was put in a thermo-hygrostat (85° C., RH: 95%, water vapor partialpressure: 0.54 atm) and treated with water vapor for 1 hour. Then, theprecursor fiber was heated at a rate of 200° C./hour and was calcined at900° C. in air for 30 min to obtain a porous titania fiber.

The resulting titania fiber had an average diameter per a monofilamentof 15 μm and a BET specific surface area of 0.4 m² /g. The pore volumeby the nitrogen absorption method was less than 0.01 cc/g and the volumeof pores having a pore diameter of not less than 10 angstroms was lessthan 0.01 cc/g. The average tensile strength was 1.0 Gpa per amonofilament. According to the XRD analysis, the fiber was ananatase-form titanium oxide.

Using the porous titania fiber, a catalyst fiber was prepared accordingto the same manner as that descried in Example 22. An amount of thevanadium oxide carried on and in the catalyst fiber was 5.3% by weightbased on the catalyst fiber. According to the SEM observation, therewere large amount of oxide particles adhered on the outer surface of thefiber as shown in FIG. 2, because the pore volume is small and thereforevanadium oxide particles can not be charged in the fiber. According tothe EPMA analysis, the fractured surface of the catalyst fiber of thecross section was analyzed. As a result, it was confirmed that only asmall amount of the vanadium oxide was carried in the catalyst fiber.

according to the same manner as that described in Example 22, a catalystperformance test was conducted. As a result, a nitrogen oxide removalefficiency was 29%.

COMPARATIVE EXAMPLE 4

The precursor fiber which was obtained in the same method as in Example1was put in a thermo-hygrostat (85° C., RH: 95%, water vapor partialpressure: 0.54 atm) and treated with water vapor for 3 hours. The, theprecursor fiber was heated at a rate of 200° C./hour and was calcined at600° C. in air for 30 min to obtain a porous titania fiber.

The resulting titania fiber had an average diameter per a monofilamentof 15 μm and a BET specific surface area of 90 m² /g. The pore volume bythe nitrogen absorption method was 0.06 cc/g and the volume of poreshaving a pore diameter of not less than 10 angstroms was 0.01 cc/g. Theaveage tensile strength was 0.6 Gpa per a monofilament. According to theXRD analysis, the fiber was an anatase-form titanium oxide.

Using the porous titania fiber, a catalyst fiber was prepared accordingto the same manner as that described in Example 22. An amount of thevanadium oxide carried on and in the catalyst fiber was 6.1% by weightbased on the catalyst fiber. According to the SEM observation, therewere vanadium oxide particles on the outer surface of the catalyst fiberalthough the amount of the oxide particles is smaller than that inComparative Example 3. According to the EPMA analysis, the fracturedsurface of the catalyst fiber of the cross section was confirmed thatthe vanadium oxide was carried in the catalyst fiber in an amount ofsmaller than that in each of Examples 22 to 24.

According to the same manner as that described in Example 22, a catalystperformance test was conducted. As a result, a nitrogen oxide removalefficiency was 44%.

What is claimed is:
 1. A continuous fiber of titania having an averagediameter per a monofilament of from 5 to 50 μm, which has a BET specificsurface area of 10 m² /g or more, a pore volume of 0.05 cc/g or more, avolume of pores having a pore diameter of not less than 10 angstromsbeing 0.02 cc/g or more and an average tensile strength per amonofilament of 0.1 GPa or more, or which has an average tensilestrength per a monofilament of 0.5 GPa or more, wherein said continuousfiber is obtained by adding water to an alcohol solution of titaniumalkoxide to carry out a hydrolysis reaction and a polymerizationreaction of the titanium alkoxide, to form a polymer, and spinning saidpolymer to obtain said continuous fiber of titania.
 2. A continuousfiber of titania having an average diameter per a monofilament of from 5to 50 μm and an average tensile strength per a monofilament of 0.5 Gpaor more, wherein said continuous fiber is obtained by adding water to analcohol solution of titanium alkoxide to carry out a hydrolysis reactionand a polymerization reaction of the titanium alkoxide, to form apolymer, and spinning said polymer to obtain said continuous fiber oftitania.
 3. A continuous fiber of titania having an average diameter pera monofilament of from 5 to 50 μm, a BET specific surface area of 10 m²/g or more, a pore volume of 0.05 cc/g or more, a volume of pores havinga pore diameter of not less than 10 angstroms being 0.02 cc/g or moreand an average tensile strength per a monofilament of 0.1 GPa or more,wherein said continuous fiber is obtained by adding water to an alcoholsolution of titanium alkoxide to carry out a hydrolysis reaction and apolymerization reaction of the titanium alkoxide, to form a polymer, andspinning said polymer to obtain said continuous fiber of titania.
 4. Thecontinuous fiber of titania according to any one of claims 1 to 3,wherein said continuous fiber contains silica in an amount of 40% byweight of less based on the fiber.
 5. The continuous fiber of titaniaaccording to any one of claims 1 to 3, wherein said continuous fibercontains an anatase-form titanium oxide as a main crystal.
 6. Acontinuous fiber according to any one of claims 1-3, wherein the amountof water added is from 1.5 to 4.0 mole per 1 mole of titanium alkoxide.7. A continuous fiber according to any one of claim 1-3, wherein duringthe hydrolysis, the amount of water consumed is from 1.5 to 1.95 molesper 1 mole of titanium alkoxide.
 8. The continuous fiber according toclaim 7, wherein the amount of water consumed is from 1.6 to 1.90 molesper 1 mole of titanium alkoxide.
 9. A continuous fiber according to anyone of claim 1-3, wherein the polymer obtained by said hydrolysisreaction is insoluble in an alcohol.
 10. The continuous fiber accordingto claim 9, wherein said polymer is soluble in an organic solvent otherthan an alcohol.